Environmental Data Needed for Public Health Assessments

A Guidance Manual

June 1994

Use of trade names is for identification only and does not imply endorsement by the Agency for Toxic Substances and Disease Registry, the Public Health Service, or the US Department of Health and Human Services.

DATA NEEDS WORKGROUP

Gary H. Campbell
Paul A. Charp
Rita Ford
Emilio González
Diane L. Jackson
John H. Mann
Stephanie R. Ostrowski
Lynn C. Wilder
Betty C. Willis, Editor

FOREWORD

Public health assessments challenge ATSDR to integrate environmental sampling data, health outcome data, and community concerns successfully in the evaluation of the health implications of hazardous substances released to the environment. Doing so enables ATSDR staff members to make the difficult decisions as to why, where, and for whom public health actions should be undertaken .

ATSDR's public health activities have documented human exposure to releases from about 40 percent of the hazardous waste sites Agency scientists have examined; potential exposure could occur at another 40 percent. In fiscal year 1992, sufficient environmental data were available to indicate the need for health investigations at about 35 percent of the sites evaluated by public health assessments. Included were sites where concern was for current or past exposures to hazardous substances released from the site .

More important to the focus of this document, there was insufficient environmental data to determine whether health investigations should be conducted at approximately 40 percent of the sites evaluated. Thus, environmental data are critical to ATSDR's public health algorithm, but only to the extent that such data can be used in a manner that contributes to and facilitates the Agency's public health practice .

Recognizing that data are collected at hazardous waste sites for a variety of purposes, ATSDR has focussed this guidance on the needs of the environmental public health professional. This guidance is not intended to supplant the professional judgment and discretion of those responsible for sampling and monitoring the environment; instead, it provides a framework for further dialogue and discussion among health assessors and environmental risk managers .

The draft guidance was made available for public comment through publication in the Federal Register and was distributed to federal, state, and local entities; private consultants and corporations; and trade/professional organizations. Comments received were considered and, when appropriate, incorporated into the document. ATSDR is responsible for the technical accuracy of this guidance and is committed to updating it as new information becomes available. Comments from the users of this guidance document are welcome. Please send comments to Robert C. Williams, P.E., DEE, Director, Division of Health Assessment and Consultation, ATSDR, E-32, 1600 Clifton Road, Atlanta, Georgia 30333.

Robert C. Williams, PE, DEE
Director
Division of Health Assessment and Consultation
Agency for Toxic Substances and Disease Registry

Barry L. Johnson, Ph.D.
Assistant Surgeon General
Assistant Administrator
Agency for Toxic Substances and Disease Registry

TABLE OF CONTENTS

DATA NEEDS WORKGROUP

FOREWORD

INTRODUCTION

SAMPLING STRATEGY

DATA QUALITY INFORMATION

ELECTRONIC DATA TRANSFER

GENERAL INFORMATION NEEDS

A. SITE IDENTIFIERS

B. SITE HISTORY

C. GEOGRAPHIC AND DEMOGRAPHIC DATA

D. RELATIONSHIP TO NEARBY COMMUNITY

E. SUBSTANCES IDENTIFIED

F. ANALYTICAL INFORMATION

SOIL EXPOSURE PATHWAY

SURFACE WATER EXPOSURE PATHWAY

SEDIMENT EXPOSURE PATHWAY

GROUNDWATER EXPOSURE PATHWAY

A. WELL SURVEY

B. WATER SOURCES

C. HYDROGEOLOGY

D. GROUNDWATER MONITORING

E. ANALYTICAL DATA

AIR EXPOSURE PATHWAY

A. AMBIENT AIR DATA

B. STACK EMISSIONS DATA

C. SOIL GAS DATA

D. INDOOR AIR QUALITY DATA

E. INDOOR DUST DATA

FOOD-CHAIN EXPOSURE PATHWAY

A. NONSAMPLING INFORMATION

B. SAMPLING INFORMATION

C. BIOTA STUDIES

IDENTIFICATION OF PHYSICAL HAZARDS

RADIOLOGIC PARAMETERS AND SAMPLES

INTRODUCTION

A PHA is the evaluation of data and information on the release of hazardous substances into the environment in order to assess any past, current, or future impact on public health, to develop health advisories or other recommendations, and to identify studies or actions needed to evaluate and mitigate or prevent human health effects. For further information on the PHA process and ATSDR's methodologies for evaluating public health effects, see ATSDR Public Health Assessment Guidance Manual, March 1992. The PHA evaluates three primary types of information: environmental data, community health concerns, and health outcome data. This data needs document addresses only environmental data needs .

During analysis of human exposure pathways, environmental data are used to determine how human exposure may have occurred, may be occurring, or may occur. An exposure pathway consists of five elements:

1. source (landfill, spill, etc.);
2. transport media (groundwater, air, etc.);
3. exposure point (drinking water well, food source, shower, etc.);
4. route of exposure (ingestion, inhalation, etc.); and
5. receptor population (families, schoolchildren, etc.).

During preparation of a public health assessment, ATSDR must evaluate specific data that address pathways, especially at potential exposure points. Much of that needed information is available in reports of remedial investigations (RIs) and other environmental studies conducted by EPA, federal facilities, state agencies, and PRPs. Other environmental information critical to exposure pathway analysis, such as contaminant concentrations at off- site human exposure points, is not as likely to be available at the beginning of the RI process. The following sections describe specific environmental data that are needed for a thorough evaluation of potential human exposure to hazardous substances and the related health effects. The availability of this information early in the remediation process could contribute to the timely identification of needed public health actions and would eliminate the need for "preliminary health assessments," which usually conclude that more data are needed for full evaluation of the public's exposure .

ATSDR depends on other agencies or corporate PRPs to generate the environmental data necessary to determine the degree of public exposure to toxic chemicals at hazardous waste sites. Most of the environmental information that ATSDR needs is the same as that routinely required by EPA at NPL/hazardous waste sites. ATSDR typically requires additional information in the following categories:

1. contaminant concentrations in all off-site media to which the public may be exposed;
2. an appropriate detection limit and level of quality assurance/quality control (QA/QC) in samples to ensure the resulting data are adequate for assessing possible human exposures;
3. discrete samples that reflect the potential range of exposure of the public;
4. surface soil and sediment samples not deeper than 3 inches;
5. more extensive biota studies, and analyses of edible portions only;
6. more ambient and indoor air sampling; and
7. lists of physical hazards and barriers to site access.

This document is intended to provide general guidance that will help persons responsible for designing hazardous waste site characterizations include the data that ATSDR needs to develop a public health assessment of the site. It is recommended that, when possible, ATSDR review draft environmental sampling workplans for areas at each NPL site where there is an exposure potential to provide site-specific guidance on data that will be needed to address site-related public health issues that may arise.

SAMPLING STRATEGY

Certain information should be included in any sampling study .

1. Geographic area or source the sampling plan is designed to represent.
2. Intent of sampling strategy, e.g., to define average or range of concentrations.
3. Rationale or statistical method used to select sampling locations, i.e., random, grid, stratified, composite, grab, etc.
4. Sampling equipment used and method(s) for decontamination between samples.
5. Location and rationale for selection of background samples.

DATA QUALITY INFORMATION

1. Data quality objectives (DQOs) -- The anticipated use for which samples were taken, which then determines the types of laboratory analysis used; sensitivity of the analytical technique; detection limits; confidence limits; precision, accuracy, representativeness, completeness, and comparability (PARCCs); appropriate sampling design; and resulting data quality.
2. QA/QC requirements -- The criteria by which data accuracy and precision are judged.

When formulating DQOs for sampling and analysis of contaminated media at human exposure points (water supply wells, playground soils, etc.), the level of QA/QC should not be less than that used for risk assessment data (Levels III to V), as specified in the EPA Office of Solid Waste and Emergency Response (OSWER) Directive 9355.0-7B, March 1987, Data Quality Objectives for Remedial Response Activities Development Process, and the OSWER Directive 9285.7-09A, June 1992, Final Guidance for Data Usability in Risk Assessment (Parts A & B), or current versions of these documents. These documents are available from the US Environmental Protection Agency, OSWER, 401 M Street, S.W., Washington, D.C. 20460.

The ATSDR data evaluation process is discussed in detail in Appendix C of the ATSDR Public Health Assessment Guidance Manual (reference Federal Register, 57 FR 21987, May 26, 1992).

ELECTRONIC DATA TRANSFER

Electronic transfer greatly speeds the review and analysis process by eliminating the need for duplicative data entry and verification. Also, data in an electronic format can be imported to a Geographic Information System (GIS) so that disparate, geographically based information, such as contaminant distributions, census data, and land uses, can be integrated and interpreted. Generally, the entire analytical data set should be transmitted, rather than only selected or summary data. However, if the data set is extremely large, the health assessor may request that only a subset of the data be transmitted. ATSDR supports the use of electronic reporting methods and is actively pursuing their use during preparation of public health assessments.

GENERAL INFORMATION NEEDS

A. SITE IDENTIFIERS

1. Site name and alias
2. Site address or location
3. Site type (e.g., mine tailings, landfill, surface impoundment, spill, etc.)
4. EPA technical contact's name and phone number (e.g., Remedial Project Manager, On-Scene Coordinator, etc.)
5. Descriptions of problems/concerns
6. Current owner's name

1. Dates of operation and significant events (e.g., fires, changes in ownership or products, etc.)
2. Descriptions of previous releases and actions taken by EPA or the facility to remedy them
3. NPL listing document, i.e., why the site was listed on the NPL
4. Descriptions of physical barriers to prevent pollutant transport (e.g., liners, slurry walls, fences, dikes)
5. Current CERCLA and Resource Conservation and Recovery Act (RCRA) status of site
6. Current structural condition of containers, vessels, and buildings holding substances
7. Current and past operational information regarding the treatment, storage, or disposal of hazardous waste at the site
8. Current use (and past uses, if different) of all buildings and areas where the public or workers may be exposed to contaminants, e.g., former pesticide formulation building and outside rinse area converted to day care center or office space

1. Plotting of the site on the USGS quadrangle map, including the scale and map name if the complete map is not furnished
2. Political geography, i.e., city/town, county, state
3. Distance from site to closest residence
4. Approximate population residing within 1 mile of site or within the potentially affected area, whichever is greater
5. Sensitive land uses and features within 1 mile of the site or within the potentially affected area (e.g., schools, day care facilities, hospitals, retirement homes, streams, rivers, wetlands, aquifer recharge zones, water wells, etc.)
6. Copies of photographs or databases that depict past or current site conditions, including aerial photographs, satellite imagery, and GIs coverage (databases)
7. Proposed land transfers
8. Sensitive or potentially impacted land leases on site or off site

1. On-site activities and the estimated number of people involved in each activity (e.g., working, dirt-biking, camping, hunting, fishing, etc.)
2. Copy of the community relations plan
3. Types of barriers or signs used to prevent public access
4. Estimated frequency of on-site activities
5. Number and types of other potential environmental contamination sources within 1 mile of the site (or within the potentially affected area), including RCRA operating industrial facilities and other NPL or CERCLA Information System (CERCLIS) sites

1. List of chemical names and Chemical Abstract System (CAS) numbers (if known)
2. Estimate of the quantities of contaminants released to each medium (soil, air, surface water, and groundwater)
3. Maximum concentration, range, and extent of contamination in each medium (including biota)
4. Identification of waste materials and quantities
5. Documentation of any chemical, mechanical, meteorologic, or other phenomena that might rapidly alter the current physical state of the chemicals present or the general condition of the site (e.g., earthquake zone, flood plain, etc.)

1. All analytical results for each sample taken (raw data may be requested under certain circumstances), in addition to documents that summarize data
2. Detection and quantitation limits for all analytical data
3. Description of the level of QA/QC used and copies of the QA/QC results and data validation reports
4. Blank and spike sample results (specify lab or field samples)
5. Care and decontamination of tools, instruments, and sampling equipment in the field to prevent cross-contamination of samples
6. Sample storage protocol and holding times
7. Analyses of total concentrations, not only RCRA extraction analyses concentrations
8. Analyses that identify which form of a chemical is present if toxicity of the agent's various forms is significantly different (e.g., chromium III and chromium VI, elemental mercury and methylated mercury, etc.)

SOIL EXPOSURE PATHWAY

1. Exact sample locations, including descriptions and map locations, and the purpose of the sampling
2. Depth of sampling points: specify if sample is a vertical composite of soil between specified depth ranges (e.g., 0-3 inches, 3-12 inches, 1-3 feet)
3. Type of sample (e.g., grab or composite)
4. Sampling scheme for composite samples (e.g., composite of five grab samples from a 100-square-foot grid, etc.)
5. Constituents analyzed for, analytical methods used, detection limits, and concentrations detected
6. Date of sampling
7. Discrete samples (grab) as well as composite samples because composited samples may not be representative of the maximum contaminant concentration to which individuals are exposed
8. Type of soil (sandy, silty, clayey, etc.)
9. Description of vegetative cover
10. Land use or special features during sampling

SURFACE WATER EXPOSURE PATHWAY

1. Indication on map(s) of site location, boundaries of the 100-year flood plain, location of surface waters, and all surface water samples
2. Locations of all downstream surface water intakes for a distance of potential impact from the site
3. Identification and descriptions of National Pollution Discharge Elimination System (NPDES) effluents from the site and sources upstream and downstream of the site at distances potentially affecting the surrounding community (copies of NPDES permits and compliance reports may also be requested)
4. Past, current, and future uses of surface water on site and downstream (e.g., recreational, agricultural, drinking water, livestock watering, etc.)
5. Hydrologic characteristics
6. Relationship of surface water to groundwater
7. Copies of surface water sampling record and log, including sample locations and site conditions, e.g., water flow rate and/or depth, visual observations, etc.
8. pH and specific contaminant concentrations
9. Sampling and analytical methods used, detection limits, QA/QC data, and concentrations detected
10. Identification and description (including a map when appropriate) of any storm water drainage system on or adjacent to the site

SEDIMENT EXPOSURE PATHWAY

Sediments may also be mechanically disturbed and transported to possible human exposure points by dredging. Therefore, sampling and analysis of the dredged sediments, as well as the stream channels and impoundments, may be needed at some sites .

Contaminated sediments are not always found in constantly wet drainage areas. Many drainage ditches, surface impoundments, and ephemeral streams associated with releases of hazardous waste are dry part of the year. To prevent confusion between "soil" and "sediment," ATSDR defines sediment to be any solid material, other than waste material or waste sludge, that lies below a water surface; that has been naturally deposited in a waterway, water body, channel, ditch, wetland, or swell; or that lies on a bank, a beach, or floodway land where solids are deposited. For best evaluation of the potential exposure of the public, sediment samples, like soil samples, should be shallow (0-3 inches). The information listed below is needed for ATSDR's analysis of the sediment pathway.

1. Descriptions and locations on map of samples obtained
2. Depths of sampling points: specify if sample is a composite of soil between specified depth ranges (e.g., 0-3 inches, 3-12 inches, 1-3 feet, etc.)
3. Type of sample (e.g., grab or composite)
4. Sampling scheme for composite samples (e.g., composite of five grab samples from a 100-foot length of stream, whether the sampling program was designed to collect samples at regular intervals or from depositional areas, etc.)
5. Constituents analyzed for, analytical methods used, detection limits, QA/QC data, and concentrations detected
6. Date of sampling event and site conditions at that time

GROUNDWATER EXPOSURE PATHWAY

Groundwater pathways analysis and public health recommendations can be enhanced by the following approaches to groundwater monitoring:

1. Correlation of groundwater contaminants measured in site monitoring wells to contaminants measured in water supply wells can be greatly improved if some of the site monitoring wells are screened in the same groundwater zone as the water supply wells.
2. Because of the heterogeneous nature of groundwater systems, water supply wells and springs within or at the leading fringe of a groundwater contamination plume usually need more than a one-time sampling to be evaluated for possible human exposure. Quarterly monitoring for at least one year is preferred.
3. Valid comparisons between analyses of metals from groundwater samples and EPA drinking water standards can be made only if the groundwater samples are NOT FILTERED during sampling; EPA drinking water standards and health studies are based on total metals (UNFILTERED samples). Unfiltered samples should always be taken at points of exposure, e.g., private wells, municipal drinking water systems, etc. All groundwater data, for filtered and unfiltered samples, should be provided to ATSDR.
4. A few tap water samples should be included in any sampling of contaminated municipal or community wells because concentrations of contaminants measured at the wellhead may vary by an order of magnitude or more from concentrations measured at the drinking water taps in the system. Environmental samples at human exposure points (drinking water taps) provide a better data set than wellhead samples to evaluate actual human exposure.

Several types of information are needed for the groundwater exposure pathway analysis.

A. WELL SURVEY

1. Well survey and inventory within at least 1 mile of the site or within the potentially affected area, whichever is greater.
2. An inventory of a larger area downgradient of any known groundwater plumes, depending on site-specific hydrogeology and the extent of contamination. The well inventory should include the number, total depth, screen interval, well use, yield, status, installation date, pump type and age, and location of all local wells and developed springs.

Water sources designated by the following categories:

1. Monitoring wells
2. Facility water supply wells
3. Municipal/utility wells, springs, or reservoirs
4. Residential wells or springs or small, unregulated water systems
5. Commercial/industrial production wells
6. Irrigation wells (including wells that are part of lawn-watering systems)
7. Community wells, such as wells serving mobile home parks
8. Piezometers
9. Livestock water wells/springs

Descriptions of site-specific and regional hydrogeology, including these characteristics:

1. Depth, thickness, extent, name, and characteristics (including flow direction) of all groundwater zones and aquifers affected or potentially affected by contaminants
2. Depth, thickness, extent, name, and characteristics (including flow directions) of all local drinking-water aquifers
3. Vertical and lateral extent of groundwater contamination
4. Natural geochemistry (may be the same as background) of all contaminated groundwater zones and drinking water aquifers

D. GROUNDWATER MONITORING

1. Dates and frequency of past and current monitoring
2. List of analytes and detection limits
3. Sampling procedures
4. Water level measurement procedures
5. Dates of and procedures used for aquifer tests

Analytical results of groundwater monitoring, including the following information:

1. For each sample, field measurements for temperature, conductivity, and pH
2. Tables of analytical results listed by sample location
3. Any available summaries of analytical results in which the maximum concentrations of contaminants are identified
4. QA/QC analyses for different sampling episodes
5. Analytical results of metal contaminants derived from unfiltered groundwater samples
6. Water level measurements, calculated gradients, potentiometric contour maps, and figures
7. Monitoring well construction logs, boring logs, and site-specific cross-sectional maps
8. Descriptions of past, current, or planned groundwater remedial actions, including provision of alternative water supplies
9. Descriptions and results of any geophysical, geochemical (including tracer studies), or soil-gas surveys performed for the purpose of defining sources and extent of groundwater contamination
10. Descriptions and locations of all known or surmised facility- or site-related sources of groundwater contamination. Non-site-related sources may also be included if pertinent to contamination of water supply wells or springs.
11. Descriptions and locations of any on-site or near-site groundwater/surface water recharge/discharge areas, such as sinkholes, sinking or disappearing streams, stream bank or drainage ditch seeps, leachate seeps, or undeveloped springs

Adverse health effects (acute and chronic) associated with inhalation of air contaminants are a common concern of citizens living and working near hazardous waste sites. Air emissions from past or current production processes, as well as volatilization of organic compounds, airborne particulates, and acid gases from hazardous waste areas, may expose residents who live or work near the sites to contaminants at levels of health concern.

Hazardous waste areas from which air releases may be significant are surface impoundments, where there may be leaking drums or tanks containing volatile organic compounds, landfills that produce methane gas, which can migrate, waste piles of materials that may be easily entrained by winds or that contain volatile organic contaminants, and contaminated soils that may become entrained in the air by winds or vehicular traffic. Air emissions may also be generated by excavation, landfarming or bioremediation, air stripping, pond aeration, incinerator stack emissions and ash, and handling of decontaminated soil.

Air releases from past and/or current production processes may cause off-site deposition of contaminants that may lead to soil, biota, and surface water contamination, which in turn may result in the population near the site having secondary exposure. Therefore, site characterization should include an evaluation of production area air releases, meteorologic data (including wind rose or wind speeds and directions), and, possibly, modeling of those releases to determine potential off-site air-exposure points and deposition areas that may need to be sampled. Grab samples are generally not very representative of the long-term exposure the public may receive from a facility, since air concentrations can vary widely. If grab samples are taken, ATSDR recommends that several samples representative of the area be taken over time to assess the areal distribution and variation in concentration of the contaminants. Information relevant to the air pathway is listed below.

A. AMBIENT AIR DATA

1. Locations where samples were taken, including descriptions and illustrations on maps
2. Meteorologic conditions, temperature, wind speed, and wind direction when samples were taken (i.e., which samples were upwind, and which were down-wind), cloud cover, (i.e., sunny, overcast), time of year, and time of day or night
3. Sampling log, including descriptions of activities in the area during sampling that may have contributed to concentrations of constituents detected (e.g., 10 feet from busy intersection, 20 feet downwind from bulldozers excavating contaminated soil, etc.), and descriptions of measures taken to reduce emissions if ambient air monitoring is in conjunction with remediation activities (e.g., dust-control measures, etc.)
4. Height at which samples were taken. Samples should be taken in the breathing zone (4-5 feet above ground)
5. Descriptions of sampling methods used and constituents collected by each method (personal monitors, fixed monitoring stations, Tenax tubes, total particulate or PM10, Drager® tubes, OVA® , HNU® , etc.)
6. Sampling frequency and dates (duration of continuous or integrated composite sampling, grab samples, etc.). If grab samples are taken, samples may need to be taken both at night and during the day in case the concentrations are affected by the change in meteorologic conditions.
7. Constituents analyzed for, analytical methods used, detection limits, QA/QC, and concentrations detected
8. Ambient air sampling where people may be exposed at on- and off-site locations if fugitive air emissions are the only source of potential human air exposure and if on-site or fence-line sampling indicates contaminants are present at levels that could cause adverse health effects
9. Ambient air data from the maximum predicted off-site exposure locations to ensure that modeling predictions are accurate and to protect public health if there are current stack emissions from production areas or remedial technologies and if modeling of those emissions indicates a potential for people off site to be exposed to constituents at levels that may cause health effects
10. Ambient air samples even if modeling does not indicate a potential for off-site exposure at levels of health concern but exposure is plausible and there is community concern about site emissions

1. Detailed descriptions of the treatment technology or manufacturing process associated with each stack, including design drawings, raw feed materials, operating temperatures and conditions, products and by-products of the system, any air pollution control equipment, etc.
2. All permits (state and federal, Clean Air Act, polychlorinated biphenyls [PCB], and hazardous waste [RCRA]), if permitted under those programs or, if a CERCLA unit, all documents relevant to the unit's design and operating requirements
3. All compliance reports required under any of the previously described permits and any other documents that discuss past planned and unplanned air releases
4. All stack testing or trial burn results for the units (including testing or trial burn plans, sampling, analytical, and QA/QC reports, and any written reviews of the data)
5. Identification of the closest meteorologic station and general meteorologic conditions (including wind rose, prevalence of air stagnation events, or other unusual conditions for that area) and a determination that the information is representative of the meteorologic conditions at the site and surrounding areas
6. Any air modeling for the stack(s) and/or fugitive emissions at the site (including all parameters used in the modeling, such as land use, terrain features, nearby building dimensions, meteorologic conditions used or dates and source of meteorologic data used in the modeling, flue gas temperature and velocity, stack height, contaminant emission rate, etc.)

1. Analytical results from any soil gas surveys and a description of the sample locations and survey methods
2. Measurements of flammable and explosive gases, such as methane or ethylbenzene, at landfills and other waste source areas, as well as at nearby buildings where such gases may be generated, migrate, or accumulate
3. Descriptions of calibration gases and concentrations needed in addition to the instrument readings of a combustible gas meter or other instrument calibrated to determine concentrations at or above the lower explosive limit of gases under investigation
4. Gas pressure measurements to estimate how far soil gas contaminants may migrate from their source to human exposure points, such as occupied residences
   
   1. Permanent gas monitoring wells should be equipped with a permanent pressure gauge that should be read before sampling.
   2. Vertical and lateral zones of soil gas movement can best be determined when gas monitoring wells are screened in the most likely subsurface zone of movement and not over the entire depth of the unsaturated zone.
5. Investigation of buried utility lines that lie beneath or adjacent to the hazardous waste area to determine if they serve as preferential pathways for soil gas movement from the source area into occupied buildings

Indoor air sampling data may be needed to determine potential health effects on building occupants (workers and/or residents) if on-site buildings that are occupied (or may be occupied by people in the future) are constructed of contaminated materials or the buildings became contaminated during use. Indoor air sampling may also be needed if gases or volatile organic compounds are known to be migrating through the soil or if soil gas measurements around the building indicate that gases may accumulate in the building. If flammable or explosive atmospheres are possible, instruments capable of detecting flammable and explosive gases at and above the lower explosive limit should be used. Specific indoor air sampling data are needed.

1. Type of instruments and sample collection methods used (include air volume sampled)
2. Analytical data and analytical methods used, including detection limits for all contaminants, calibration of equipment, and QA/QC procedures and results
3. Date, time, and temperature when samples were taken
4. Diagram of building showing sampling locations
5. Descriptions of building construction materials and significant construction features (on concrete slab, basement, number of stories, below grade, on stilts, etc.)
6. Descriptions of sampling locations, including type of room (bedroom, den, garage, basement, attic, process area, or storage area, etc.); height in the room; and distances from significant structures in the room, such as ceilings, hoods, vents, workbenches, chemical storage or use areas, doors or other large openings, etc.
7. Descriptions of building air flow before and during the sampling (e.g., was the building unoccupied and closed with no air circulation? Was central heating or air conditioning operating for sufficient time to reach equilibrium in air quality?)
8. Descriptions of other contaminants that may be present in the air because of normal building use (especially important for residential sampling), such as chemicals or solvents used for hobbies, freshly painted surfaces, cleaners, lawn care products, tobacco smoke, etc.
9. Data from aggressive air sampling of buildings that are/may be contaminated with metals, particulates, or fibers. Aggressive air sampling is any method used to agitate particulates or fibers that may have settled out of the air or that could easily become airborne because of human activity (usually the use of high-powered fans or leaf blowers). The air should be agitated either during the entire time that an air sample is being collected or at regular intervals during the sampling period. Aggressive air sampling gives the most conservative of worst-case results of a given contaminant in indoor air.
   1. ATSDR recommends that such sampling be performed because it is difficult to interpret surface wipe sampling data for health purposes.
      
   2. Aggressive air sampling should be conducted when buildings are not occupied, with the indoor air constantly "stirred up" to simulate worst-case conditions.
      
   3. Contaminants may be in homes as a result of contaminated soil being tracked in, contaminated clothing being brought home from work, or air deposition through open windows, vents, etc.

In some cases, indoor air sampling may not be appropriate or possible. If sampling must be done while the building is occupied, conducting aggressive air sampling for particulate and fiber contaminants may increase the exposure of occupants by making contaminants airborne. If this is a concern, dust sampling should be used to determine human exposure .

A typical scenario for which indoor dust sampling may be appropriate would be a residential setting where soil lead contamination is at or near levels of health concern. In this case, lead contamination's being tracked indoors and being ingested by infants or young children would warrant indoor dust sampling. Any contaminant that can be analyzed from a particulate sample can be measured via dust sampling .

If indoor dust sampling is conducted, the data listed below are needed.

1. Surface area vacuumed (i.e., square feet).
2. Description of the area sampled. Is activity in the area high or low? Is the area accessible (i.e., kitchen floor vs. behind couch, or a combination)? Are floors in the sampled building or area carpeted, hardwood, concrete, linoleum, etc.?
3. Description of the sampling equipment and collection media.
   
   1. High Efficiency Particulate Air (HEPA) filters are recommended.
   2. ATSDR recommends that samples not be taken from the resident's vacuum cleaner because the resident may use the vacuum in other areas besides the home (e.g., garage, workplace, etc.) and the smaller particles are not captured in a vacuum bag. Some studies have shown that more contaminants are attached to small particles than to large particles.
4. A copy of the indoor dust sampling plan. The detection limits that will dictate how large a sample to collect must be at or below the level of health concern for the contaminants present.
5. Are there any other possible contributing factors to the contamination besides surface loading (i.e., hobbies, lead paint, etc.)?

If the results of indoor dust sampling indicate a health threat, sampling after an indoor cleanup will be needed to verify that the threat has been eliminated. In theory, this should be easy. If the cleaning is sufficient, there should be no dust remaining to collect and therefore no contamination. However, this has not always been the case. In some instances, the contaminant concentrations appeared to have increased as a result of remediation. ATSDR recommends that the same area be vacuumed before and after cleanup but acknowledges that it will sometimes be necessary to vacuum a larger area after cleanup to get enough dust to analyze. If that is required in the sampling plan, the plan should also include a requirement for wipe sampling a same-sized area before and after cleanup. Wipe sampling will document the contaminant surface loading before and after remediation.

FOOD-CHAIN EXPOSURE PATHWAY

When planning and designing an investigation of food-chain contamination, it is important to have a well-designed biota sampling protocol, with sample size large enough to be statistically significant (more than 20 samples per location per sampling episode are recommended when parametric statistical methods will be used). In particular, organisms of different species, ages, or reproductive status should not be sampled without strong justification. For example, when assessing the impact of contaminated sediment upon the edible fish populations in a stream, results of analyses of tissues from bottomfeeding fish should not be combined with those from water-column feeders; because of their different feeding habits, very different effects may be expected. Discrete (grab) samples are preferred because ATSDR tries to determine the maximum contamination in order to model worst-case scenarios .

Special handling of biologic samples needs to be considered. Some analytical procedures require that live or fresh-frozen fish be transported to the lab immediately for analysis; the accuracy of other procedures may not be affected if formalin-preserved specimens or those held frozen for weeks or months are used. Such considerations, along with any special problems encountered, should be included in an appendix to the document for quality assurance review.

When contamination of consumable plants and/or animals is suspected, specific data are needed by ATSDR to evaluate the food-chain pathway .

A. NONSAMPLING INFORMATION (past/present)

1. Animal and plant species that may be eaten by people if these species are potentially affected by the site (e.g., annual animal population or crop volume harvested)
2. Descriptions of populations consuming each potentially contaminated crop and animal (e.g., residential gardens containing tomatoes, corn, and peas consumed by owners [include ethnicity, if known]; local subsistence hunting for rabbits, dove, and deer; commercial and subsistence fishing for salmon and catfish; commercial beef cattle ranches and feedlots in the area; etc.)
3. Descriptions of past, present, and intended future land use

If contamination exists only on site:

1. Sampling and analysis of edible plants and on-site edible animal species
2. Sampling and analysis of off-site edible animal species likely to pass through the contaminated area

C. BIOTA STUDIES

When biota studies are performed:

1. A copy of the protocol used, including how each species was harvested; how representative samples were selected of each species; what portions were sampled and analyzed; size of samples; special specimen-handling procedures, including sample storage procedures; contaminants analyzed for and rationale for their selection; methods used and their detection limits, etc.
2. All analytical results and reports, including any QA/QC data and reports, and a list of samples and their corresponding sample number
3. A sample size of at least 20 individuals per species, per episode
4. Analysis of edible portions
5. Analysis of individual (grab) rather than composite samples. If composite samples are necessary because of the size of the species, include compositing strategy.
6. A control population of at least 20 individuals from a comparable uncontaminated location for background levels

IDENTIFICATION OF PHYSICAL HAZARDS

Listed below are data needed for identification and evaluation of physical hazards.

1. Descriptions and locations of physical barriers that would prevent access to on-site physical hazards.
2. Descriptions and locations of on-site and perimeter warning signs that would warn trespassers of dangerous conditions. Descriptions should specify language(s) in which the signs are written and whether the signs are sufficient to warn all subpopulations in the surrounding communities.
3. Descriptions of all existing potential physical hazards at the site. Examples of physical hazards include these:
   
   1. confined spaces, especially underground areas (danger of entrapment and accumulation of toxic or suffocating gases);
   2. industrial equipment (danger of falls from such equipment or of unsecured equipment falling onto individuals);
   3. explosive or hazardous vapors, especially soil gases;
   4. explosive, shock-sensitive, air- or water-reactive, or incompatible materials stored on site;
   5. electrocution hazards, such as exposed wires and unsecured fuse boxes;
   6. structures that are unsafe or deteriorating because of poor repair or weather damage;
   7. open pits or vats containing chemicals or water;
   8. sinkholes or soil erosion;
   9. stored materials (danger of collapse because of deteriorating packaging);
   10. leachate (may be strongly acidic or caustic, causing chemical burns); and
   11. cables, chains, wires, ropes (danger of entanglement, breaking under loads).

RADIOLOGIC PARAMETERS AND SAMPLES

1. The types of instruments used (e.g., solid state, ionization, scintillation) and the manufacturer and model number for each type of detector and probe
2. Calibration information such as the radioisotope used (e.g., Cs/Ra/Co), date of last calibration, and the instrument efficiency for each radioisotope
3. Detection limits for each radioisotope, including length of time the sample was counted, the statistical error, total counts, and/or counts per minute
4. For laboratory instruments, the average background value and how often the background was determined
5. For multi-channel analyzers, specification of channels and whether a standard was run before and/or following the analysis
6. Field measurements information, including the following elements:
   
   1. probe location (e.g., distance from the surface or surface contact)
   2. background reading, what instrument was used, and where the background data were collected
   3. results with a notation identifying gross or net readings
   4. the proper units (e.g., counts per minute converted to dose rate or to exposure rate)
7. Smears results
   Although the level of uncertainty can be high because of variability in the sampling technique, these are indicative of the mobility of radioactive materials from surfaces. The results should indicate the area covered by smears (e.g., 100 sqcm) and what type of laboratory instrument (GeLi, HPGe, a/ß, etc.) was used to analyze the samples.
8. Air sample reports
   These should include a description of the sampler; the height above ground of the sampling system; volumetric flow through the filter; sample time; and area, pore size, and type of filter used (charcoal, AgI, etc.). See Air Exposure Pathway section for additional information needs.
9. Soil sample reports
   These should include information about the area represented by the sample (grid size) and sampling depths. The number of samples collected should be stated, and, if the results are for composite samples, reports should reflect the number of individual samples that made up the composite before sample counting. See Soil Exposure and Sediment Exposure Pathways sections for additional information needs.
10. Water sample reports
    These should include information on whether the sample was filtered before counting and how the samples were prepared (e.g., ashed, CO-precipitated and radioisotope percent recovery, or distilled, etc.). Information on the type of EPA method used to analyze the water sample is also needed. See Surface Water Exposure and Groundwater Exposure Pathways sections for additional information needs.
11. Radon level determinations
    These should state what type of detector was used (e.g., charcoal canisters, alpha track, etc.). If indoor measurements were taken, was the house or building vacant, sealed, or inhabited? What time of year was the sample collected, and what were the indoor and outdoor temperatures during the collection period? How long was the detector in the structure? Was the laboratory that performed the monitoring approved by the EPA radon program?